RU2723354C2 - High-power extractor for juices - Google Patents

Abstract

FIELD: food industry.

SUBSTANCE: group of inventions relates to high output juice extractor. Extractor for juices contains a base; installed on base first and second supports; first squeezing element and second squeezing element. Second squeezing element is eccentric relative to the first squeezing element. Drive element is configured to actuate at least one of the first squeezing element and the second squeezing element. First squeezing element comprises external housing gear. Second squeezing element comprises inner housing gear engaged with outer housing gear. First squeezing element and second squeezing element are rotated by engagement of outer housing gear and inner housing gear.

EFFECT: use of group of inventions simplifies design of juicer and improves quality of produced product.

11 cl, 17 dwg

Description

Technical field

The present invention relates to high-power juice extractors, and more specifically, to a high-power juice extractor of simple design, in which the gear ratio can be easily adjusted to control the peripheral speeds of the first extractor and second extractor and to prevent leakage of juice.

BACKGROUND OF THE INVENTION

In general, a juice extractor is a type of juicer capable of squeezing juice from various materials (hereinafter referred to as the “squeeze object”), such as vegetables or fruits, by crushing, grinding and / or compressing the material.

As shown in FIG. 1-8, the juice extractor 100 according to the prior art comprises a base 110 which serves as a support, a support member 130 fixed to the base 110, a squeezing unit 150 rotatably mounted in the supporting member 130, a feeding unit 170 that supplies the squeezing object into a squeezing unit 150, a tapping unit 180, which draws the cake from the squeezing unit 150, and a drive unit 140, which rotates the squeezing unit 150. In addition, the juice extractor includes a cover 120 for placement inside the above components.

As shown in FIG. 2 and 5, the squeezing unit 150 comprises a first extractor 151 and a second extractor 155 located in the first extractor 151, the first extractor 151 being connected to and driven by the third shaft 1455, and the second extractor 155 connected to and driven by the second shaft 1453 rotation. The rotating shaft of the first extractor 150, i.e. the third shaft 1455, and the rotating shaft of the second extractor 155, i.e. the second shaft 1453, are mounted in an eccentric manner.

The support element 130 comprises a first support 131, a second support 133 and a third support 121, which are mounted on the base 110 and are spaced apart from each other in the longitudinal direction. The first support 131 and the third support 121 are mounted on both sides of the second support 133 in the longitudinal direction. The third support 121 may serve as a cover to close an opening formed on one side of the cover 120. The support member 130 may further comprise at least one reinforcing support 123 for reinforcing and supporting the third support 121, the reinforcing support being attached to the base at its lower end and connected to the third support 121 on the side.

The support member 130 supports the first shaft 1451, the second shaft 1453 and the third shaft 1455 rotatably, with bearings placed between the support member and the respective shafts.

The first extractor 151 comprises a first cylindrical part 1511 and a first annular part 1513 connected to the first cylindrical part 1511 so as to support the first cylindrical part in the radial direction. The first annular portion 1513 is connected to a third shaft 1455 rotatably connected to a second support 133, and a bearing is placed between them. The third shaft 1455 can be inserted into the inner part of the first annular part 1513 and connected to it. The third shaft 1455 is connected to the first annular part 1513 and extends in a direction opposite to the first cylindrical part 1511. The first extractor 151 is supported in the radial direction since one side of the first annular part 1513 is connected to the third shaft 1455 in the longitudinal direction. The other side of the first cylindrical part 1511 of the first extractor 151 is supported in the radial direction by at least one support roller 161, which is rotatably mounted in the third support 121. The support roller 161 extends beyond the third support 121 towards the first cylindrical part 1511 so as to support the first the cylindrical part 1511 rotatably. A support ring 1515 is provided at the end of the other side of the first cylindrical portion 1511, and the support ring 1515 is rotatably contacted with the support roller 161 so as to support the first cylindrical portion 1511. As shown in FIG. 5, the support roller 161 is mounted in the third support 121, so that the support roller is in contact with the outer circumferential surface of the lower portion of the cylindrical part 1511. The third shaft 1455 has a hollow body, and the third extractor 151 is a structure with the right side open, as seen in the longitudinal direction .

The rotating shaft, i.e., the second shaft 1453, of the second extractor 155 is rotatably supported by the first bearing 131 on one side, the bearing being placed between them, and the other side being rotatably supported by the third bearing 121, the bearing being placed between them. The third shaft 1453 penetrates into the third hollow shaft 1455, and, as shown in FIG. 2 and 5, is set so that the center of the third shaft is offset from the center of the third shaft 1455 connected to the first extractor 151.

A second extractor 155 is provided on the second shaft 1453 so that the second shaft and the second extractor rotate together. The second extractor 155 is located in the first extractor 151. The second extractor 155 contains a second cylindrical part 1553 and several second annular parts 1551, which are spaced from the second cylindrical part in the longitudinal direction and connected to the second cylindrical part 1553 on its outer circumferential surfaces. The second shaft 1453 is connected to the second cylindrical part 1551 so that the second shaft rotates together with the second cylindrical part.

The second extractor 155 is located in the first extractor 151. The center of rotation of the first cylindrical part 1511 is eccentric with respect to the center of rotation of the second cylindrical part 1553, so that the centers of rotation are different from each other. As shown in FIG. 5, the first cylindrical part 1511 and the second cylindrical part 1553 are installed by spacing their centers of rotation so that the upper gap between the first cylindrical part 1511 and the second cylindrical part 1553 is greater than the lower gap between the first cylindrical part 1511 and the second cylindrical part 1553. In FIG. 5, reference numeral 1455a denotes the center of rotation of the first extractor 151, and 1453a denotes the center of rotation of the second extractor 155. As shown in FIG. 5, the center of rotation of the second cylindrical part 1553 is offset downward relative to the center of rotation of the first cylindrical part 1511.

The squeeze object S is inserted into a large gap between the first cylindrical part 1511 and the second cylindrical part 1553, and the introduced object is directed downward to the small gap by gravity, as well as the first cylindrical part 1511 and the second cylindrical part 1553, which rotate in the direction indicated by the arrow in FIG. . 5, so that the object of squeezing is clamped between the inner circumferential surface of the first cylindrical part 1511 and the outer circumferential surface of the second cylindrical part 1553.

The drive unit 140 comprises an electric motor 141, a first gear 1471 and a third gear 1475, which are meshed with the first shaft 1451, a second gear 1473, meshed with the second shaft 1453, and a fourth gear 1477, meshed with the first shaft 1455.

The electric motor 141 is mounted on the base 110, and the first shaft 1453 and the third shaft 1455 are driven by the electric motor 141. The pulley is mounted on the shaft of the electric motor 141, and the pulley is mounted on the left end of the first shaft 1451, when viewed in the longitudinal direction. Two pulleys are connected to each other by a belt 143 so that the rotation of the electric motor 141 is transmitted to the first shaft 1451.

The first gear 1471 is mounted on the first shaft 1451 from the side of the pulley, and the second gear 1473, which is meshed with the first gear 1471, is mounted on the part of the second shaft 1453, which protrudes beyond the third shaft 1455 towards the left side in the longitudinal direction. A third gear 1475 is mounted on the right end of the first shaft 1451 in the longitudinal direction, and a fourth gear 1477, which is meshed with the third gear 1475, is mounted on the third shaft 1455.

When the motor 141 is operating, the shaft 1451 rotates with a belt 143 and a pulley, the second shaft 1453 rotates by connecting the first gear 1471 and the second gear 1473, and the third shaft 1455 rotates by connecting the third gear 1475 and the fourth gear 1477. Thus, the second extractor 155 connected to the second shaft 1453 and the first extractor 151 connected to the third shaft 1455 rotate. The first extractor 151 and the second extractor 155 rotate in the direction indicated by the arrow in FIG. 5, and the gear ratio of the first gear 1471, the second gear 1473, the third gear 1475 and the fourth gear 1477 is adjusted to make their peripheral speeds equal.

As shown in FIG. 2-5, a feed unit 170 is provided for introducing a squeeze object between the first cylindrical part 1511 of the first extractor 151 and the second cylindrical part 1553 of the second extractor 155. The discharge unit 180 is provided for discharging the cake existing between the first cylindrical part 1551 and the second cylindrical part 1553, after pushups. The supply unit 170 and the discharge unit 180 are mounted on the upper part, which corresponds to a wide gap between the first cylindrical part 1511 and the second cylindrical part 1553.

The feed unit 170 comprises a hollow feed casing 173, a screw 177 rotatably mounted in the feed casing 173, and a hollow feed funnel 171 diverging from the feed casing 173, which is open outwardly in the longitudinal direction of the first cylindrical portion 1511, inwardly into the feed casing 173 moreover, the diameter of the feed hopper increases towards the top. The feed funnel 171 diverges upward from the feed casing 173. The feed unit 170 is preferably mounted so as to be offset from the rotation direction of the first extractor 151 and the second extractor 155.

One part of the supply casing 173 is located between the inner surface of the first cylindrical part 1511 and the outer surface of the second cylindrical part 1553, and the other part is open outward from the first cylindrical part 1511 of the first extractor 151 in its longitudinal direction. The supply casing 173 is attached to the third support 121, with one part of the supply casing located on the left side of the third support 121 in the longitudinal direction, and the other part is located on the right side of the third support 121 in the longitudinal direction. A feed hopper 171 is connected to a portion of the feed casing 173, which is located on the right side of the third support 121. A drive element 178 may be provided in the longitudinal direction on the right end of the feed casing 173 to rotate the screw 177. The left end of the feed casing 173 supports the screw in the longitudinal direction 177 rotatably. Under the feed casing part 173, a discharge opening 174 is made, which is located between the inner surface of the first cylindrical part 1511 and the outer surface of the second cylindrical part 1553.

When the squeeze object is fed into the feed hopper 171 with the drive unit 178 operating, the object lowered into the feed casing 173 through the feed funnel 171 is moved to the left in the longitudinal direction by a screw 177, which rotates in the feed casing 173. Then the object is lowered between the inner surface of the first cylindrical part 1511 and the outer surface of the second cylindrical part 1553 through the outlet 174 made in the supply casing 173, and the lowered object is directed to the narrow part between the first cylindrical part 1511 and the second cylindrical part 1553, as shown in FIG. 5 so that the object is pressed and squeezed between the inner surface of the first cylindrical part 1511 and the outer surface of the second cylindrical part 1553.

As shown in FIG. 5, in the case where the second extractor 155 is eccentric downward, the squeeze object is pressed and squeezed as it moves downward, and is subjected to maximum pressing at the center of the load. As the object passes the center of load, the pressing force gradually decreases.

The first cylindrical portion 1511 provided in the first extractor 151 is provided with several through holes 1512, as shown in FIG. 3 and 4. On the inner surface of the first cylindrical part 1511, a screen 153 may be provided, comprising several small holes. The size of the small hole is determined so that the juice is discharged, and the cake is not discharged.

The juice, pressed and squeezed between the first cylindrical part 1511 and the second cylindrical part 1553, is discharged through small holes and through holes 1512 made in the first cylindrical part 1511, and part of the cake or the whole cake is attached to the inner side of the screen 153 and rotates with it. A separating element 189 for separating the cake from the inner side of the first cylindrical part is located outside the cylindrical part 1511 and is separated from the first cylindrical part. The separating element 189 injects fluid inwardly from the outside of the first cylindrical portion 1511. The separating element 189 is, for example, a spray nozzle and connected to a cooler (not shown) of an air conditioning unit so as to inject cold fluid (eg, air) into the first cylindrical portion 1511. The separating member 189 may be a spray nozzle extending in the longitudinal direction of the first cylindrical portion 1511 and containing nozzle openings. By injecting cold fluid, the oxidation of the components of the juice extractor 100 can be suppressed.

Juice squeezed from the squeeze object flows down through the first cylindrical part 1511 and then is collected in a collection block (not shown) using the collecting and guiding block 157 provided under the first cylindrical part 1511. The collecting and directing block 157 is located under the first cylindrical part 1511 and inclined and extends to a predetermined length so as to direct the juice pouring from the first cylindrical part 1511. The collecting and guiding unit 157 is preferably made so as to be larger than the projection area of the first cylindrical part 1511.

The outlet block 180 comprises an outlet casing element located between the inner surface of the first cylindrical part 1511 and the outer surface of the second cylindrical part 1553, and extending outward in the longitudinal direction, the outlet guide part 189 communicating with the outlet casing element and extending downward, and an auger 187 mounted with the possibility of rotation in the outlet casing. The outlet housing member comprises an outlet housing 183 located between the inner surface of the first cylindrical portion 1511 and the outer surface of the second cylindrical portion 1553, and having an arcuate cross section, and the first outlet housing 185 extending downward from the outlet housing 183 in the longitudinal direction of the first cylindrical portion 1511. The outlet casing 183 and the first outlet casing 185 are in communication with each other. The outlet guide portion 189 extends downward from the first outlet housing 185.

The inner end of the screw 188 is rotatably supported by the outlet casing 183, and the outer end is rotatably supported by the first outlet casing 185. The outlet casing 183 comprises a cylindrical casing support 1831, and the inner end of the screw 188 is rotatably inserted into the inner end of the casing support.

The right end of the first exhaust casing 185 in the longitudinal direction contains a drive element 188 for rotating the screw 188, and the screws 178 and 188 are connected to and operate from the engine 141. The exhaust casing 183 under the separating element 189 for injecting fluid and contains a concave part in the direction of the separating element 189. The first outlet casing 185 may be made of a hollow tube and have an arcuate shape.

The outlet unit 180 is set to be eccentric with respect to a direction opposite to the direction of rotation of the first extractor 151 and the second extractor 155, as shown in FIG. 5.

The cake, attached to the inner surface of the first cylindrical part 1511 and rotated with it, is separated from the first cylindrical part 1511 by a fluid injected from the separating element 189, and then lowered to the outlet casing 183 of the outlet casing element and then moved outward by a screw 187 rotating in outlet casing 183 when viewed in the longitudinal direction. Then the cake is brought down through the outlet guide portion 189 connected to the first outlet casing 185.

The juice extractor 100 of the prior art has a complex structure. In addition, since the support shaft of the first cylindrical part 1511 is made of a hollow body, a bearing having a large diameter must be provided, and juice removal is not easy.

It is difficult to adjust the first to fourth gear ratio 1471-1477 to make the peripheral speed of the first extractor 151 and the second extractor 155 the same.

State of the art

Patent Literature

International application PCT / KR2010 / 009221 (December 22, 2010).

Technical problem

Accordingly, the present invention takes into account the problems described above, and the aim of the present invention is to provide a high-power juice extractor having a simple configuration that allows you to easily adjust the gear ratio to adjust the peripheral speed of the first extractor and the second extractor and to prevent juice that is squeezed from extruded squeeze object, flowed along the second shaft.

Technical solution

In order to achieve the above purpose, a high-power juice extractor is provided, comprising: a base; the first and second supports, which are spaced from each other in the longitudinal direction and are installed on the base; the first squeezing element, which is a hollow cylinder, open towards the second support, is located between the first support and the second support, is rotatably supported on the first support by the support shaft of the outer casing, and is made with several outlet openings; a second squeezing member that is rotatably supported on the second support by a support shaft of the inner case, which is eccentric with respect to the support shaft of the outer case, and is located in the first squeezing member so as to be eccentric with respect to the first squeezing member; and a drive member configured to actuate at least one of the first squeezing member and the second squeezing member, the first squeezing member comprising a gear of the outer housing, the second squeezing member comprising a gear of the inner housing that is engaged with the gear of the outer housing and the first squeezing member and the second squeezing member rotate by engaging the gears of the outer casing and the gears of the inner casing.

High-power juice extractor contains: base; the first and second supports, which are spaced from each other in the longitudinal direction and are installed on the base; the first squeezing element, which is a hollow cylinder, open towards the second support, is located between the first support and the second support, is rotatably supported on the first support by the support shaft of the outer casing, and is made with several outlet openings; a second squeezing member that is rotatably supported on the second support by a support shaft of the inner case, which is eccentric with respect to the support shaft of the outer case, and is located in the first squeezing member so as to be eccentric with respect to the first squeezing member; and a drive member configured to actuate at least one of the first squeezing member and the second squeezing member, the first squeezing member and the second squeezing member comprising a portion with an increased cross-sectional area in the same position in the longitudinal direction.

The first squeezing element contains the gear of the outer casing, the second squeezing element contains the gear of the inner casing, which is meshed with the gear of the outer casing, and the first squeezing element and the second squeezing element rotate due to the engagement of the gear of the outer casing and the gear of the inner casing.

The straight lines passing from the support shaft of the inner case and the support shaft of the outer case are parallel to each other.

The high-power juice extractor according to claim 1 or claim 3, wherein an annular element is provided at the open end of the first squeezing element, which is made of a semicircular plate so as to leave the inner upper part of the first squeezing element open, and the annular element contains a first annular element, two the second annular element and the third annular element. The first annular element is located outside the gears of the outer casing and the gears of the inner casing. The third annular element is separated from the first annular element, is located in the longitudinal direction, and is located on the side of the gear of the outer casing and the gear of the inner casing, and the annular part of the third annular element coincides with the inner diameter of the outer casing. The second annular elements are placed between the first annular element and the third annular element, the gear of the inner casing being placed between the second annular elements, and the annular part of the second annular element coincides with the inner diameter of the first squeezing element.

The annular part of the first annular element coincides with the outer diameter of the open end of the first squeezing element, while the upper part of the first annular element is made with an outer notch, the arcuate convex part is made in the center of the outer notch, and the circumference of the center of the outer notch is equal to or greater than the outer circumference of the gear of the inner case.

The upper part of the third annular element is made with the first inner cut, the arcuate convex part is made in the center of the first inner cut, and the circumference of the center of the first inner cut is equal to or greater than the outer circumference of the gear of the inner housing. The center of the third annular element is made with a second inner cutout, which coincides with the outer diameter of the second squeezing element and is open down.

The thickness of the second annular element is greater than the thickness of the gear of the inner housing of the second squeezing element.

At the end of the second squeezing element, which faces the other side of the open end, that is, to the lower surface of the first squeezing element, there is a protrusion protruding towards the lower surface of the first squeezing element.

The first squeezing element and the second squeezing element comprise a central part whose cross-sectional area is greater than the cross-sectional area of both ends.

The cross-sectional area of the first squeezing element and the second squeezing element gradually increases from both ends to the center.

Beneficial effects

Due to the configuration described above, according to the high-power juice extractor, the configuration is simple, the number of gears needed to rotate the first squeezing element and the second squeezing element is reduced so that the gear ratio can be easily adjusted by controlling the peripheral speed of the first extractor and the second extractor. In addition, it is possible to prevent leakage along the second shaft of juice, which is squeezed out of the pressed squeezing object.

Description of graphic materials

FIG. 1 is a perspective view illustrating an extractor according to the prior art.

FIG. 2 is a cross-sectional view schematically illustrating an extractor according to the prior art.

FIG. 3 and 4 are perspective views schematically illustrating the configuration of an extractor according to the prior art.

FIG. 5 is a cross-sectional view taken along line A-A in FIG. 2.

FIG. 6 is a cross-sectional view of a portion of a feed unit that is provided in an extractor according to the prior art.

FIG. 7 is a perspective view schematically illustrating a portion of a discharge unit that is provided in an extractor according to the prior art.

FIG. 8 is a cross-sectional view of a portion of the outlet unit shown in FIG. 7.

FIG. 9 is a cross-sectional view schematically illustrating a high-power juice extractor according to one embodiment of the present invention.

FIG. 10 is a perspective view illustrating parts of squeezing elements of a high-power juice extractor according to an embodiment of the present invention.

FIG. 11 is a cross-sectional view illustrating squeezing elements of a high-power juice extractor according to an embodiment of the present invention.

FIG. 12 is a cross-sectional view illustrating a first squeezing member of a high-power juice extractor according to an embodiment of the present invention.

FIG. 13 is a cross-sectional view illustrating a second squeezing member of a high-power juice extractor according to an embodiment of the present invention.

FIG. 14-16 are views schematically illustrating the engagement ratio of extractors in a high power juice extractor according to an embodiment of the present invention.

FIG. 17 is a cross-sectional view illustrating the squeezing elements of a high-power juice extractor according to a modified example of the present invention.

Principle of invention

Next, with reference to the accompanying drawings, a high-power juice extractor according to one embodiment of the present invention will be described in detail.

FIG. 9 is a cross-sectional view schematically illustrating a high-power juice extractor according to one embodiment of the present invention. FIG. 10 is a perspective view illustrating parts of squeezing elements of a high-power juice extractor according to an embodiment of the present invention. FIG. 11 is a cross-sectional view illustrating squeezing elements of a high-power juice extractor according to an embodiment of the present invention. FIG. 12 is a cross-sectional view illustrating a first squeezing member of a high-power juice extractor according to an embodiment of the present invention. FIG. 13 is a cross-sectional view illustrating a second squeezing member of a high-power juice extractor according to an embodiment of the present invention. FIG. 14-16 are views schematically illustrating the engagement ratio of extractors in a high power juice extractor according to an embodiment of the present invention. FIG. 17 is a cross-sectional view illustrating the squeezing elements of a high-power juice extractor according to a modified example of the present invention.

In connection with the figures of graphic materials, the term “longitudinal direction” generally describes the direction going from the front to the back of the juice extractor, and the term “internal” or “inside” generally describes the direction going from the front to the inside of the squeezing element, while the term “outward direction” or “outward” generally describes a direction opposite to the inward direction or inward direction. ”

As shown in FIG. 9, a high-power juice extractor 200 according to one embodiment of the present invention comprises a base 210, a support member, a first squeeze member 270, a second squeeze member 290, a feed unit 220, a take-away unit (not shown), a drive member 240, a collecting container and a casing 280 to accommodate parts of the above components.

According to this embodiment, the base 210 serves as a supporting frame for the juice extractor 200. On its upper part, the base 210 is provided with a support element, an engine M and a collecting container. One side of the casing is open, and the collecting container 260 may pass through the opening of the casing 280.

The support element comprises a first support 230 and a second support 250. The first and second supports are spaced apart from each other in the longitudinal direction and are attached to the upper surface of the base. In particular, the first support 230 is provided on one side of the base in the longitudinal direction, and the second support 250 is provided on the other side.

The first support 230 comprises several plates connected to each other. The first support 230 is made with a through hole in the longitudinal direction and rotatably supports the support shaft 276 of the outer housing of the first squeezing element 270 by means of a bearing.

The second support 250 contains several plates connected to each other. Between the plates of the second support 250, a drive element 240 is provided.

The upper part of the second support 250 is made with a through hole in the longitudinal direction and rotatably supports the supporting shaft 295 of the inner housing of the second squeezing element 250 by means of a bearing. The second support 250 comprises at least one support roller 251. The support roller 251 is rotatably supported by the second support 250 by means of a bearing. A support roller 251 is provided under the opening of the first squeezing member 270. The support roller 251 contacts the first squeezing member 270 in the circumferential direction, supporting the first squeezing member 270.

The first support 230 and the second support 250 may be made of one plate.

As shown in FIG. 9-12, the first squeezing member 270 is a hollow cylinder open toward the second support 250. The first squeezing member 270 is located between the first support 230 and the second support 250. The first squeezing member 270 is rotatably supported by the outer shaft support shaft 276 through a bearing.

The first squeezing element 270 comprises an outer casing 271, an inner sieve 279, a support shaft 276 of the outer casing, an amplifier 278 of the support shaft and a gear 277 of the outer casing.

The outer casing 271 is a hollow cylinder, open towards the second support 250. The outer casing 271 is made with several outlet openings 273. The outlet openings 273 are spaced apart from each other in the longitudinal direction and the circumferential direction. At the open end of the outer casing 271, a flange 275 of the outer casing is provided, which extends outward from the end of the outer casing 271 in the radial direction. The flange 275 of the outer casing is made with several holes in the longitudinal direction, and the gear 277 of the outer casing is attached to the flange of the outer casing. In the gear 277 of the outer casing, several holes are made in the longitudinal direction, and these holes are spaced apart from each other in the circumferential direction, and the gear 277 of the outer casing is engaged with the flange of the outer casing by fixing bolts in the holes.

An inner sieve 279 is provided on the inner surface of the outer casing 271. The inner sieve 279 is attached to the inner surface of the outer casing 271 and rotates with the outer casing 271. The inner sieve 279 is a sieve in which several small holes are provided. The size of the small holes made in the inner sieve 279 is smaller than the size of the outlet openings 273. The juice is drained through the small holes, and the cake remains in the inner sieve 279.

The supporting shaft 276 of the outer casing is made in the form of a rod extending in the longitudinal direction. One end of the outer shaft support shaft 276 is attached to the outer surface of the other side, that is, to the lower part of the outer housing 271. The outer shaft support shaft 276 is rotatably supported by the first bearing 230 by means of a bearing. The support shaft 276 of the outer casing is connected to the central part of the outer casing 271, which becomes the center of rotation.

The support shaft amplifier 278 is made of an annular plate. The center of the support shaft amplifier 278 is positioned so as to coincide with the support shaft 276 of the outer casing. The support shaft amplifier 278 is attached to the outer surface of the lower part of the outer housing 271 by a screw. The support shaft 276 of the outer housing extends through the center of the support shaft amplifier 278. The support shaft 276 of the outer casing passing through the support shaft amplifier 278 is welded to the support shaft amplifier 278.

The gear 277 of the outer casing is made in an annular form. A gear is provided on the inner circumferential surface of the gear 277 of the outer case. The gear 277 of the outer casing is attached to the flange 275 of the outer casing. As shown in FIG. 11 and 14, the diameter D11 of the outer circumference of the gear 277 of the outer casing is identical to the inner diameter D1 of the outer casing 271. Reference numeral D13 in FIG. 14 indicates the diameter of the circumference of the valleys of the gear 277 of the outer casing. The gear 277 of the outer casing is engaged with the gear 293 of the inner casing of the second squeezing member 290, which is inscribed in and is engaged with the gear 277 of the outer casing.

As shown in FIG. 9-11 and 13, the second squeezing member 290 is a cylinder extending in the longitudinal direction. A second squeezing member 290 is provided in the first squeezing member 270. The second squeezing member 290 is rotatably supported by the inner shaft support shaft 295, which is supported by the second bearing 250 by means of a bearing. A second squeezing member 290 is provided in the first squeezing member 270 in a position in which the second squeezing member is eccentric with respect to the first squeezing member 270 by an inner shaft support shaft 295, which is eccentric with respect to the outer housing support shaft 276.

The second squeezing element 290 comprises an inner housing 291, a support shaft 295 of the inner housing, a gear 293 of the inner housing and an annular element.

The inner housing 291 is made of a cylinder extending in the longitudinal direction. The inner casing 291 is a hollow casing and is open toward the second support 250. The inner casing 291 is provided in the outer casing 271. The outer diameter D2 of the inner casing 291 is smaller than the inner diameter D1 of the outer casing 271. The center of the inner casing 291 is eccentric downward from the center of the outer corps 271.

In the inner case 291, a hollow protrusion 2911 is provided having a circular cross-section that protrudes beyond the outer surface of the opposite side, i.e., the lower part, the open part of the inner case toward the lower surface of the outer case 271. The protrusion 2911 contacts the inner lower surface of the outer case 271, or a small gap is formed between the end of the protrusion 2911 and the inner lower surface. Due to the formation of the protrusion 2911, the lower surface of the inner casing 291 does not contact the lower surface of the outer casing 271. When the inner casing 291 is inserted into the outer casing 271, the protrusion 2911 directs the insertion depth of the inner casing 291 so that the gear 293 of the inner casing is directly engaged gear 277 of the outer casing. The center of the lower part of the inner housing 291 is made with a hole 2913 for input, passing in the longitudinal direction. A rotating shaft, i.e., a support shaft 295 of the inner housing 291, is inserted into the input hole 2913.

The supporting shaft 295 of the inner casing is made in the form of a rod extending in the longitudinal direction. The left end of the support shaft 295 of the inner housing in the longitudinal direction is made with part 2953 for input, containing a stepped part. The input portion 2953 passes through the input hole 2913 made in the lower part of the inner housing 291. A threaded portion may be provided in the input portion. A portion 2953 for introducing the support shaft 295 of the inner case is attached to the outer surface of the lower part of the inner case 291 by a fastener 2951. The fastener 2951 includes a nut or the like. The support shaft 295 of the inner case is attached to the bottom of the inner case 291 and extends through the bore of the inner case 291. The other side of the support shaft 295 of the inner case is rotatably supported on the second support 250 by means of a bearing. The support shaft 295 of the inner case is the central shaft of the inner case, which becomes the center of rotation. The support shaft 295 of the inner case is eccentric with respect to the support shaft 276 of the outer case. The support shaft 295 of the inner casing and the support shaft 276 of the outer casing are installed so that the straight lines passing from the support shaft 295 of the inner casing and the support shaft 276 of the outer casing are parallel to each other.

The gear 293 of the inner housing is made of an annular plate. A gear is provided on the outer circumference of the gear 293 of the inner case. The gear 293 of the inner case is attached to the open end of the inner case 291. The gear 293 of the inner case is inscribed in and engages with the gear 277 of the outer case. Reference numeral D21 in FIG. 15 indicates the diameter of the outer circumference of the gear 293 of the inner case, and D23 indicates the diameter of the circumference of the valleys of the gear 293 of the inner case.

The first squeezing member 270 and the second squeezing member 290 are inscribed in the outer circumference D21 of the gear of the inner casing 293 and the circumference D13 of the troughs of the gear 297 of the outer casing, and the circumference D23 of the troughs of gear 293 of the inner casing is inscribed in and engaged with the outer circumference D11 of the gear 277 of the outer casing.

As shown in FIG. 10, an annular element is provided at the open ends of the first and second squeezing elements 270 and 290. The annular element is made of a semicircular plate, so that the upper part of the first squeezing element 270 is disclosed. The annular element comprises a first annular element 297, two second annular elements 292 and a third annular element 299, which are arranged in order from right to left in the longitudinal direction and are in contact with each other. The second annular elements 292 are placed between the first annular element 297 and the third annular element 299.

As shown in FIG. 14, the first annular element 297 is made of a semicircular plate and placed between the gear 277 of the outer casing and the second support 250. The first annular element 297 is in contact with the outer surface of the gear 277 of the outer casing in the longitudinal direction. The first annular element 297 is attached to the second support 250. The annular part of the first annular element 297 coincides with the outer diameter of the gear 277 of the outer casing and is located in the lower part.

The upper part of the first annular element 297 is made with an outer cutout 2975. The arcuate convex part is made in the center of the outer cutout 2975. The circumference of the center of the outer cutout 2975 is equal to or greater than the outer circumference D21 of the gear 293 of the inner case.

The first annular element 297 is made with a hole 2971 of the shaft extending in the longitudinal direction. The shaft hole 2971 is made in a position that is the center of rotation of the inner case 291. The support shaft 295 of the inner case passes through the shaft hole 2971.

The third annular element 299 is spaced from the first annular element 297 and is located inside in the longitudinal direction. The third annular element 299 is a substantially semicircular plate. The third annular element 299 is located inside the gear 277 of the outer casing and the gear 293 of the inner casing. As shown in FIG. 16, the annular part of the third annular element 299 coincides with the inner diameter D1 of the outer casing 271.

The upper part of the third annular element 299 is made with the first inner cutout 2993. The arcuate convex part is made in the center of the first inner cutout 2993. The circumference of the center of the outer first inner cutout 2993 is equal to or greater than the outer circumference D21 of the gear 293 of the inner case.

The center of the third annular element 299 is made with a second inner neckline 2995. The second inner neckline 2995 coincides with the outer diameter D23 of the inner housing 291. The second inner neckline 2995 is open downward. The lower ends of the third annular element 299 are separated from each other by a second inner neckline 2995.

As shown in FIG. 15, in this embodiment, two second annular elements 292 are provided, and they are made of plates. The second ring elements 292 are placed between the first ring element 297 and the third ring element 299. The second ring elements 292 are in contact with the first ring element 297 and the third ring element 299. The gear 293 of the inner casing is placed between the second ring elements 292.

The second annular element 292 has an arcuate portion on one side. The arcuate portion of the second annular element 292 is configured to match the inner diameter D1 of the outer casing 271 (the inner diameter D1 of the outer casing is identical to the outer circumference D11 of the gear 277 of the outer casing). The opposite ends of the second annular element 292 are designed to coincide with the outer circumference D21 of the gear 293 of the inner casing. The thickness of the second annular element 292 is greater than the thickness of the gear 293 of the inner housing.

The arched parts of the second and third annular elements 292 and 299 coincide with the inner diameter D1 of the outer casing 271 and serve as a guide when assembling the first squeezing element 270.

The first annular element 297, the second annular elements 292 and the third annular element 299 are made with several engaging holes 2973, 2921 and 2991 extending in the longitudinal direction, and are engaged with each other by introducing the engaging element into the engaging holes.

The supply unit 220 and the discharge unit (not shown) do not substantially differ from those of the prior art and therefore will not be described in detail.

The drive element 240 is provided under the second support 250 and is connected to the support shaft 295 of the inner housing of the second squeezing element 290. The drive element 240 comprises a motor M, a pulley and a belt. The engine M is located under the support shaft 295 of the inner casing. Pulleys are mounted for engine M and the support shaft 295 of the inner case, and a belt is entwined around the pulleys.

The drive element 240 reports the moment of rotation to the first squeeze element 270 and the second squeeze element 290 and rotates the support shaft 295 of the inner housing of the second squeeze element 290. The support shaft 295 of the inner housing rotates by the drive element 240, so that the first squeeze element 270 and the second squeeze element 290 rotate. squeezing juice.

A collecting container 260 is provided on the base 210 and is located under the first squeezing element 270. The collecting container 260 has a hollow body open upward. The size of the collecting container 260 is equal to or greater than the longitudinal length of the first squeezing element 270.

An extractor 200 for juices according to a modified example of the present invention will now be described.

As shown in FIG. 17, the first squeezing member 270 and the second squeezing member 290 are configured such that the cross-sectional area increases in the longitudinal direction in the same position. In particular, the cross-sectional area of the first and second squeezing elements 270 and 290 is larger than the cross-sectional area of both ends. In other words, the first and second squeezing elements 270 and 290 can be made so that the cross-sectional area gradually increases from the ends to the center. According to the juice extractor 200 according to this modified example, the juice is squeezed out of the object and then collected and discharged in the direction A, in which the cross-sectional area increases.

In the first squeezing member 270, a tap auger is provided for diverting the cake to the inner upper portion of the first squeezing member. The outlet screw may be made of an elastic material (e.g. rubber).

Although the present invention has been described with reference to specific exemplary embodiments, it should not be limited to these embodiments, but only to the appended claims. It should be understood that specialists in the art can change or modify embodiments without going beyond the scope and essence of the present invention.

Industrial applicability

With the high-power juice extractor according to the present invention, the configuration is simple, the number of gears necessary to rotate the first squeezing element and the second squeezing element is reduced so that the gear ratio can be easily adjusted by controlling the peripheral speed of the first extractor and the second extractor. In addition, it is possible to prevent leakage along the second shaft of juice, which is squeezed out of the pressed squeezing object.

Claims (29)

1. High-power juice extractor containing: base (210); the first and second supports (230 and 250), which are spaced from each other in the longitudinal direction and are installed on the base (210); the first squeezing element (270), which is a hollow cylinder, open towards the second support (250), is located between the first support (230) and the second support (250), is rotatably supported on the first support (230) by a support shaft (276 ) the outer case and is made with several outlet openings (273); a second squeezing element (290), which is rotatably supported by a support shaft (295) of the inner casing, which is eccentric with respect to the support shaft (276) of the outer casing, and is located in the first squeezing element (270), so as to be eccentric with respect to the first squeezing element; and a drive element (240), configured to actuate at least one of the first squeezing element (270) and the second squeezing element (290), moreover, the first squeezing element (270) contains a gear (277) of the outer casing, the second squeezing element (290) comprises a gear (293) of the inner case, which is engaged with the gear (277) of the outer case, and the first squeezing element (270) and the second squeezing element (290) rotate by engaging the gears (277) of the outer casing and the gears (293) of the inner casing. 2. A high-power juice extractor containing: base (210); the first and second supports (230 and 250), which are spaced from each other in the longitudinal direction and are installed on the base (210); the first squeezing element (270), which is a hollow cylinder, open towards the second support (250), is located between the first support (230) and the second support (250), is rotatably supported on the first support (230) by a support shaft (276 ) the outer case and is made with several outlet openings (273); a second squeezing element (290), which is rotatably supported on the second support (250) by the support shaft (295) of the inner casing, which is eccentric with respect to the support shaft (276) of the outer casing, and is located in the first squeezing element (270), so as to be eccentric with respect to the first squeezing element; and a drive element (240), configured to actuate at least one of the first squeezing element (270) and the second squeezing element (290), wherein the first squeezing element (270) and the second squeezing element (290) comprise a part with an increased cross-sectional area in the same position in the longitudinal direction. 3. High-power juice extractor according to claim 2, characterized in that the first squeezing element (270) contains the gear (277) of the outer casing, the second squeezing element (290) contains the gear (293) of the inner casing, which is engaged with the gear ( 277) of the outer casing, and the first squeezing element (270) and the second squeezing element (290) rotate due to the engagement of the gears (277) of the outer casing and the gear (293) of the inner casing. 4. High-power juice extractor according to claim 1 or 3, characterized in that the straight lines extending from the support shaft (295) of the inner housing and the support shaft (276) of the outer housing are parallel to each other. 5. High-power juice extractor according to claim 1 or 3, characterized in that at the open end of the first squeezing element (270) an annular element is provided, which is made of a semicircular plate, so as to leave open the inner upper part of the first squeezing element (270), and wherein the annular element comprises a first annular element (297), two second annular elements (292) and a third annular element (299); wherein the first annular element (297) is located outside the gear (277) of the outer case and the gear (293) of the inner case; the third annular element (299) is spaced from the first annular element (297), is located in the longitudinal direction, and is located on the side of the gear (277) of the outer casing and the gear (293) of the inner casing, and the annular part of the third annular element (299) coincides with the inner the diameter of the outer case (271); and second annular elements (292) are placed between the first annular element (297) and the third annular element (299), with the gear (293) of the inner casing being placed between the second annular elements, and the annular part of the second annular element (292) coincides with the inner diameter of the first squeezing element (270). 6. High-power juice extractor according to claim 5, characterized in that the annular part of the first annular element (297) coincides with the outer diameter of the open end of the first squeezing element (270), the upper part of the first annular element (297) is made with an outer cut-out (2975) ), while the arcuate convex part is made in the center of the outer recess (2975), and the circumference of the center of the outer recess (2975) is equal to or greater than the outer circumference (D21) of the gear (293) of the inner case. 7. A high-power juice extractor according to claim 5, characterized in that the upper part of the third annular element (299) is made with a first internal notch (2993), while the curved convex part is made in the center of the first internal notch (2993), and the center circle the first inner cut-out (2993) is equal to or greater than the outer circumference (D21) of the gear (293) of the inner case; and the center of the third annular element (299) is made with a second inner cut-out (2995), which coincides with the outer diameter (D23) of the second squeezing element (290) and is open downward. 8. High-power juice extractor according to claim 5, characterized in that the thickness of the second annular element (292) is greater than the thickness of the gear (293) of the inner housing of the second squeezing element (290). 9. High-power juice extractor according to claim 1 or 3, characterized in that a protrusion is provided at the end of the second squeezing element (290), which faces the other side of the open end, that is, the lower surface of the first squeezing element (270). (2911), protruding toward the bottom surface of the first squeezing element (270). 10. High-power juice extractor according to claim 2, characterized in that the first squeezing element (270) and the second squeezing element (290) have a central part of the cross-sectional area, which is larger than the cross-sectional area of both ends. 11. High-power juice extractor according to claim 10, characterized in that the cross-sectional area of the first squeezing element (270) and the second squeezing element (290) gradually increases from both ends to the center.

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